NO158236B - PROCEDURE AND DEVICE FOR HEATING A FLUID. - Google Patents

Description

Joints between tubular elements, e.g. a couple of radiators, boiler sections or similar.

The present invention relates to a new joint connection between tubular elements, e.g.

a couple of radiators, boiler sections or similar,

so that a liquid connection is obtained at the same time

between the individual sections.

'In the past it has been common to produce

radiators, consisting of a plurality of sections,

by performing the sections individually and then attaching

a number of sections together to provide the radiator

the desired capacity. Boilers are made in a similar way. Then it is necessary that the sections

also have means for circulating vapors or others

fluids through the sections, each section is

provided with gates which are flush with those i

the other section, and reverse threaded nipples

are screwed into the ports to provide the fluid connection. It is also common to provide a radiator, where the nipples connect the sections

are called "pressure nipples" are not threaded, but have

a double conical outer wall, which fits into

the conical wall of the ports in the radiator or boiler sections, and where the sections are pressed together under pressure to bring the nipples to seal in the bosses. Such radiators are then held together by bolts that extend from one end of the radiator to the other.

Among the problems associated with the above mentioned devices is that the bosses which receive the nipples must be exactly flush, otherwise the nipples will twist and will give a poor seal. In addition, holes must be provided in the boiler or radiator sections to allow the bolts to extend through them, which requires the use of cores during casting, and this increases the cost of manufacture. The alignment of these holes must also be maintained with very small tolerances. In addition, it takes more time to assemble the radiators, as does the cost of the through bolts, both of which are expensive. The threaded nipples were also expensive both to produce and to install, and had the additional disadvantage that the radiator sections could not be placed as close to each other as desired, thus increasing the space and reducing the heat exchange properties. In an attempt to eliminate the sealing problems with pressure nipples, it has been proposed to arrange a lead sleeve over the nipple. The lead, however, has a tendency to slip and has no holding power. Once lead is deformed, it stays deformed. It was still necessary to use through bolts to hold the sections together due to the complete lack of holding power.

When using the new joint according to the invention, radiators, boiler sections or the like can be held together without the use of bolts, clamps or other means than the nipple itself.

The joint according to the invention is of the kind which includes a tubular element with externally bevelled or conical openings in the respective sections, and the joint is characterized in that the tubular element is coated with adhesive at least at the ends and is pressed into the corresponding openings with sufficient force to displace or distort the adhesive coating so that it comes into intimate contact with the wall of the associated openings, which adhesive causes the tubular member and the radiator sections to be joined together so that the tubular member constitutes the only mechanical connection between the radiator sections , whereby the need for connecting bolts or similar bodies is made redundant.

According to another feature of the invention, the tubular part is provided with an outer surface, which is conical at least at one end, and is coated with the adhesive on the conical end.

In order for the invention to be understood more clearly and can be easily carried out, the same will now be described more fully with references to the attached drawings in which: fig. 1 is a vertical section of a nipple which can be used in the invention, and

fig. 2 is a partial view of a pair of boiler or radiator sections, showing the nipple in position.

In short, the invention consists in using a pressure type nipple which has a binder coating on the outside which is placed in position in the nipple receiving boss on a boiler or radiator, and which then holds these securely together and at the same time provides a liquid seal.

An example of a nipple in its preferred form is shown in fig. 1. In this case, the nipple 10 is of the usual design with a cylindrical bore

12 and double-conical outer walls 14. It can be made of malleable iron or other suitable material. The shape of the outer walls is essentially that of two truncated cones with the base rafts meeting in a smooth curve. The conicity of the drawings is somewhat exaggerated in order to get a better explanation of the invention. The outside of the nipple is coated with a layer of binder 16 which covers the outer surface and extends somewhat beyond the ends at 16a. The binder is preferably one of the plastics that has the property of resisting water, steam or other heat-exchanging liquids.

ker. It must have the ability to expand and contract along the material of the nipple and to fill the pores of the nipple and the section to which it is connected. Although the coating is only shown on the outside, it must be understood that the entire outside and inside can be coated. It is also preferred that it is of such a nature that, as the material ages, it becomes so that it achieves a certain degree of hardness. At the same time, it should have the property of floating during installation. When it finally stabilizes, it should be a semi-rigid material. The binder plastic may be one of those of the type including, but not necessarily limited to, polypropylene, urethane, epoxy resin and hydrocarbons.

Fig. 2 shows a pair of radiator or boiler sections 20, 21 each provided with a boss 22-22a and having a conical bore 24 and 24a A clearance groove 26 and 26a is provided at the outer end on the inside of each of the bosses at the end of boreholes 24 and 24a.

In carrying out the method, the nipple has one end inserted into one of the bores, and then the other section is lifted up and connected to the other end of the nipple - All the sections can be assembled in this way. Pressure is then applied to all the sections to bring the nipples into place.

An alternative method is to begin the assembly of the first two sections and after two sections have been assembled, place the third section on top of the first two assembled sections, and so on until the entire device is assembled. It is assumed that the composition can be carried out more quickly and a first stabilization of the binder can be started by heating the sections just before the composition.

Immediately after composition, the flow properties of the binder coating are such that the pores in the metal forming the wall of the bore in the radiator or boiler sections are filled. At the same time, there is a flow of binder into the clearance space 26-26a. This last current can be such that it completely covers the inside of the clearance space, and extends between the bosses 22-22a as shown. The binder also flows somewhat at the outer ends of the nipple, as shown at 30 and 30a. although this is in the interior of the radiator or boiler.

The binder has a good liquid property and therefore adheres firmly to the surface of the nipple and the radiator or boiler bore.

In the construction of the improved nipple, it is desirable that the outer diameter of the nipple at the apex 11 which is at the place where the two truncated cone surfaces meet, is greater than the inside diameter of the bore at the place where the clearance space 26-26a begins, so that when adjacent sections 20—21 are pressed together, the meeting surfaces between the bosses 22—22a become close to each other. This increases the holding power due to the large areas which are fixed together with a binder.

With this construction, radiator or boiler sections are held firmly together. The strength of the seal is such that it will withstand greater internal fluid pressure than the sections themselves. After a while, the material hardens to such an extent that it makes the bond semi-rigid but not brittle

there is enough elasticity in the adhesive, which is compatible with the material of the objects being held

together, to allow expansion and contraction, and even a certain amount of lateral movement of the object without serious consequences.

It should be pointed out that the plastic binder can also

be made of a material that is filled with fine

distributed metal particles and that the binder can

are burned out and leave filler material as a Rae number particle which is firmly bound together.

Claims (1)

1. Joint between a couple of radiators, boiler sections etc. and which provides a through-flow passage from one section to it second, which joint is of the kind which includes a tubular element with externally chamfered or conical ends and which is pressed into associated chamfered or conical openings in the respective sections, characterized in that the tubular element is coated with adhesive at least at the ends and is pressed into the associated openings with sufficient force to displace or distort the adhesive coating so that it comes into intimate contact with the wall of the associated openings, which adhesive causes the tubular element and the radiator sections to be connected to each other, so that the tubular element constitutes the only mechanical connection between the radiator sections, whereby the need for connecting bolts e. 1. organs is made redundant. 2- Joint as stated in claim 1, characterized in that the conical surfaces of the tubular element begin at the middle part of the tubular element and taper towards the ends. 3. Joint as stated in claim 1 or 2, characterized in that the adhesive coating includes one or more of materials, such as polypropylene, epoxy resins and urethane and which has the property that it can be displaced under the influence of pressure, so that it can flow into irregularities in the surface in the openings, and which has the property that it can be hardened after the various parts of the joint have been assembled into a unit. 4. Joint as stated in any one of claims 1-3, characterized in that clearance space, which surrounds the opening or each of the openings and in which excess adhesive can flow.